星载三线阵CCD立体测绘相机调焦技术研究
|
摘要
航天测绘在军事国防和国民经济建设等领域中的广阔应用,促进了航天测绘相机的快速发展。为解决在无地面控制点的情况下,提高航天测绘精度,提出利用传输型三线阵CCD立体测绘相机进行测绘,这种测绘方式具有直接在轨立体成像,并且能从摄取图像重构外方位元素的特点,因而在航天测绘领域占据越来越重要的地位,深受航天大国研究机构的重视。而高精度调焦是航天测绘相机成像清晰及提高测绘精度的关键技术,调焦系统是测绘相机的重要组成部分。本文在某型号星载三线阵CCD立体测绘相机研制背景下,对星载三线阵CCD立体测绘相机的调焦技术及调焦系统实现进行了深入分析研究,主要研究工作有如下几点:
1、根据光学系统成像原理,建立线阵CCD相机推扫成像模型并对关键技术指标进行分析,详细分析了导致航天相机离焦原因及离焦对相机MTF的影响程度,分析研究了离焦对测绘相机测绘精度的影响。
2、针对三线阵CCD立体测绘相机光机结构组成和工作原理,分析了三线阵CCD立体测绘相机的三条线阵CCD空间严格平行性对调焦系统调焦精度性能要求,根据三线阵CCD立体测绘相机光学系统组成设计特点和相机线阵CCD焦平面结构特点,提出适用于三线阵CCD立体测绘相机的调焦系统方案,并详细阐述了调焦系统组成和调焦工作原理,对调焦范围、调焦步长选择和焦深进行了深入计算分析。
3、三线阵CCD立体测绘相机的调焦系统是集光学系统、机械结构支撑、电气控制等环节组成于一体的复杂光机电控制系统,根据调焦应具有稳定性、快速性和准确性的要求,对调焦系统各个组成部分进行详细设计和分析,确定调焦电机驱动电路和工作频率;根据CCD焦平面的特点和调焦精度要求,详细设计了三级减速传动机构,计算各级传动比、调焦电机灵敏度和编码器的灵敏度,并根据误差分析合成理论,计算出调焦系统理论设计误差;针对调焦功能需求,在对遍历搜索法和爬山算法进行分析基础上,提出并实现粗调焦细调焦相结合的调焦算法,并根据调焦算法详细设计开环调焦控制和闭环调焦控制软件流程;提出适合三线阵CCD立体测绘相机的三台相机之间调焦互相比对的调焦策略,并对这种策略中的两种对比调焦法进行了阐述。
4、研究了调焦系统光机结构和控制系统集成装配和调焦标定测试。在实验室内对调焦系统的调焦行程、调焦精度、调焦行程内CCD焦平面的直线性和旋转性进行详细测试,测试结果满足三线阵CCD立体测绘相机对调焦系统的技术指标要求,验证了调焦系统设计合理性和实用性。在空间环境模拟器里模拟测绘相机在轨工作环境,对相机进行热光学试验,利用调焦系统测试出五种典型温度情况下测绘相机MTF值随着CCD焦平面位置变化特性曲线;然后根据测试数据分析出相机最大MTF值及对应CCD焦平面位置与温度对应关系,作为相机在轨调焦的重要依据。
Spaceflight mapping has broad application prospects in the military, nationalconstruction and other fields, which promote spaceflight mapping camera to developradpidly.The transmission type three line CCD mapping camera was proposed,because it can improve the mapping accuracy in area, where there are no groundcontrol points. The three line CCD mapping camera has the merits that it can getinflight stereo imaging, and it can reconstruct the exterior orientation elements fromthe imaging.Thus three line CCD mapping camera play more important role in thefield of spaceflight mapping, and many more researcher study on the kind of spacephotography. While focusing technology is one of the key technologies in thedevelopment of spaceflight mapping camera. As a important component of spaceflightmapping camera, focusing system determine not only the image quality but also themapping accuracy. With the research on a project of three line CCD mapping camera,this thesis emphasized on discussing the focusing technology, the design andrealization of focusing system for the three line CCD mapping camera.The specificstudy in this thesis are as follow:
1. The optical system imaging principle of spaceflight camera was analyzed, andthe push-broom imaging model for line CCD camera was established, key technicalindicators was also analyzed. The reasons of defocusing was discussed in details forspaceflight camera. The influence degree for MTF and mapping accuracy leading toby defocusing was discussed and analyzed. The focusing evaluation function based onMTF and power spectrum was proposed.and simulated.
2. The composing and imaging principle for three line array CCD mappingcamera was introduced, and the three line CCD space strict parallel converted to theCCD focal plane was analyzed in the technical requirements Focusing scheme wasproposed for the three linear CCD mapping camera. The components and workingprinciple of focusing system was introduced.
3. The focusing system is a set of optics, mechanics, electrics aspects of thecontrol system, the focusing performance should be stable, quick and precision.Therefore, the various components of the focusing system was designed and analyzedin detail to ensure that the focusing precision meet the requirement of three line CCDmapping camera, which including focusing step motor, driver power circuit, CCDfocal plane. According to the characteristics of CCD focal plane and the focusingprecision of mapping camera, three gear transmission mechanism was designed, andtransmission ratio was calculated in detailed. Accroding to the error theory, every partof focusing system was analyzed and calculated, including the focusing encodersensitivity, drive mechanism,error analysis. Focusing software was designed based onfunctional requirements for the focusing system software, research alogrithm oftraversing and climbing algorithm were introduced. It was verified that Coarsefocusing method and fine focusing method meet the precision requirement.Thefocusing stratedy suitable for three linear CCD mapping camera was proposed, andtwo contrasting focusing method for this focusing strategy were described in detail.
4. The test results indicted that the focusing system designed for three line CCDmapping camera can meet the focusing technical requiements. The curve of focusingbased on various temperature was completed in the thermo-optical test. It verified thatthe focusing system could work in the thermal vacuum tank working conditions. Theposition curve of CCD focal plane MTF vs. temperature conditions was tested.whichwas the indicator and guiding role for three line CCD mapping camera for working inorbit
1、根据光学系统成像原理,建立线阵CCD相机推扫成像模型并对关键技术指标进行分析,详细分析了导致航天相机离焦原因及离焦对相机MTF的影响程度,分析研究了离焦对测绘相机测绘精度的影响。
2、针对三线阵CCD立体测绘相机光机结构组成和工作原理,分析了三线阵CCD立体测绘相机的三条线阵CCD空间严格平行性对调焦系统调焦精度性能要求,根据三线阵CCD立体测绘相机光学系统组成设计特点和相机线阵CCD焦平面结构特点,提出适用于三线阵CCD立体测绘相机的调焦系统方案,并详细阐述了调焦系统组成和调焦工作原理,对调焦范围、调焦步长选择和焦深进行了深入计算分析。
3、三线阵CCD立体测绘相机的调焦系统是集光学系统、机械结构支撑、电气控制等环节组成于一体的复杂光机电控制系统,根据调焦应具有稳定性、快速性和准确性的要求,对调焦系统各个组成部分进行详细设计和分析,确定调焦电机驱动电路和工作频率;根据CCD焦平面的特点和调焦精度要求,详细设计了三级减速传动机构,计算各级传动比、调焦电机灵敏度和编码器的灵敏度,并根据误差分析合成理论,计算出调焦系统理论设计误差;针对调焦功能需求,在对遍历搜索法和爬山算法进行分析基础上,提出并实现粗调焦细调焦相结合的调焦算法,并根据调焦算法详细设计开环调焦控制和闭环调焦控制软件流程;提出适合三线阵CCD立体测绘相机的三台相机之间调焦互相比对的调焦策略,并对这种策略中的两种对比调焦法进行了阐述。
4、研究了调焦系统光机结构和控制系统集成装配和调焦标定测试。在实验室内对调焦系统的调焦行程、调焦精度、调焦行程内CCD焦平面的直线性和旋转性进行详细测试,测试结果满足三线阵CCD立体测绘相机对调焦系统的技术指标要求,验证了调焦系统设计合理性和实用性。在空间环境模拟器里模拟测绘相机在轨工作环境,对相机进行热光学试验,利用调焦系统测试出五种典型温度情况下测绘相机MTF值随着CCD焦平面位置变化特性曲线;然后根据测试数据分析出相机最大MTF值及对应CCD焦平面位置与温度对应关系,作为相机在轨调焦的重要依据。
Spaceflight mapping has broad application prospects in the military, nationalconstruction and other fields, which promote spaceflight mapping camera to developradpidly.The transmission type three line CCD mapping camera was proposed,because it can improve the mapping accuracy in area, where there are no groundcontrol points. The three line CCD mapping camera has the merits that it can getinflight stereo imaging, and it can reconstruct the exterior orientation elements fromthe imaging.Thus three line CCD mapping camera play more important role in thefield of spaceflight mapping, and many more researcher study on the kind of spacephotography. While focusing technology is one of the key technologies in thedevelopment of spaceflight mapping camera. As a important component of spaceflightmapping camera, focusing system determine not only the image quality but also themapping accuracy. With the research on a project of three line CCD mapping camera,this thesis emphasized on discussing the focusing technology, the design andrealization of focusing system for the three line CCD mapping camera.The specificstudy in this thesis are as follow:
1. The optical system imaging principle of spaceflight camera was analyzed, andthe push-broom imaging model for line CCD camera was established, key technicalindicators was also analyzed. The reasons of defocusing was discussed in details forspaceflight camera. The influence degree for MTF and mapping accuracy leading toby defocusing was discussed and analyzed. The focusing evaluation function based onMTF and power spectrum was proposed.and simulated.
2. The composing and imaging principle for three line array CCD mappingcamera was introduced, and the three line CCD space strict parallel converted to theCCD focal plane was analyzed in the technical requirements Focusing scheme wasproposed for the three linear CCD mapping camera. The components and workingprinciple of focusing system was introduced.
3. The focusing system is a set of optics, mechanics, electrics aspects of thecontrol system, the focusing performance should be stable, quick and precision.Therefore, the various components of the focusing system was designed and analyzedin detail to ensure that the focusing precision meet the requirement of three line CCDmapping camera, which including focusing step motor, driver power circuit, CCDfocal plane. According to the characteristics of CCD focal plane and the focusingprecision of mapping camera, three gear transmission mechanism was designed, andtransmission ratio was calculated in detailed. Accroding to the error theory, every partof focusing system was analyzed and calculated, including the focusing encodersensitivity, drive mechanism,error analysis. Focusing software was designed based onfunctional requirements for the focusing system software, research alogrithm oftraversing and climbing algorithm were introduced. It was verified that Coarsefocusing method and fine focusing method meet the precision requirement.Thefocusing stratedy suitable for three linear CCD mapping camera was proposed, andtwo contrasting focusing method for this focusing strategy were described in detail.
4. The test results indicted that the focusing system designed for three line CCDmapping camera can meet the focusing technical requiements. The curve of focusingbased on various temperature was completed in the thermo-optical test. It verified thatthe focusing system could work in the thermal vacuum tank working conditions. Theposition curve of CCD focal plane MTF vs. temperature conditions was tested.whichwas the indicator and guiding role for three line CCD mapping camera for working inorbit
引文
[1]钱曾波,刘静宇,肖国超.航天摄影测量[M].北京:解放军出版社,1990.1-10.
[2]姜景山主编.空间科学与应用[M].北京:科学出版社,2001.5-15.
[3]孙承志,唐新明,翟亮.我国测绘卫星的发展思路和应用展望[J].测绘科学,2009,3,34(2):5-7.
[4]贾平,郝志航,金光等主编.三线阵CCD立体测绘技术及其应用[M].长春光机所,2004.1-4.
[5]王之卓.摄影测量原理[M].北京测绘出版社,1979.5-7.
[6]白杉,杨秉新.航天侦察相机的发展和研发[J].影像技术,2006,2:3-6.
[7]马文坡.航天光学遥感技术[M].北京:中国科学技术出版社,2010.1-7.
[8]魏雯,李浩悦.俄罗斯军事成像侦察卫星的现状与发展[J].中国航天,2011(7):23-26.
[9]卢崇顶.国外遥感卫星发展简介(1)[J].上海地质,2001(3):28-35.
[10]庞征.法国拟打造新型太空间谍“多国天基成像系统”[J].太空探索,2011(3):48-51.
[11] Valorge,C.,40years of experience with SPOT in-flight calibration[C],ISPRSInternational workshop on radiometric and geometric calibration,Gulfport,2-5Dec200.
[12]王任享.论不同航天摄影测量传感器的摄影测量性能[J].测绘科技学报,2002(2):95-99.
[13]陈尊充,陈炳桐.关于大比例尺航测成图的体会[J].城市勘探.2002,(3):25-30
[14]王任享.无地面控制点卫星摄影测量[J].河南理工大学学报:自然科学版,2005,24(5):329-335.
[15]王任享,李晶,王新义,杨俊锋.无地面控制点卫星摄影测量高程误差估算[J]测绘科学.2005,30(6):9-11.
[16]王任享.我国无地面控制点摄影测量卫星相机[J].航天返回与遥感,2008,29(3):6-10.
[17]王任享,李晶,王新义,等.无地面控制点卫星摄影测量高程误差估算[J].测绘科学,2005,30(6):9-11.
[18]李朝辉,王智,乔克,等.三线阵立体测绘相机高精度调焦技术及实现[J].光电工程,2009,36(10):41-42.
[19]胡莘,曹喜滨.三线阵立体测绘卫星的测绘精度分析[J].哈尔滨工业大学学报,2008,40(5):695-699.
[20]李树楷.遥感时空信息集成技术及其应用[M].北京:科学技术出版社,2003,6-7.
[21]刘金国,郝志航,金光.三线阵CCD立体测绘技术及其应用[M].长春:中国科学院长春光学精密机械与物理研究所,2004,1-2.
[22] SPOT IMAGE Technical Data [OL] URL:http://www.spotimage.fr/home/system/introsat/seltec/welcome.htm,2006-10-8.
[23] Breton, E,2002, Pre-flight and in-flight geometric calibration of SPOT5HRGand HRS images. ISPRS Comm.I, Denver,CO,10-15Nov2002.
[24]姬渊.缺少控制点条件下的SPOT遥感影像定位技术研究[D]:[硕士学位论文].郑州:信息工程大学,2008.
[25]苏文博,范大昭. SPOT无控制和基于严密成像模型的研究[J].测绘与空间地理信息,2009,32(5):18-22.
[26] Jacke Grodecki and James Lutes. IKONOS Geometric Calibrations[C], Presented at ASPRS2005, Baltimore, Maryland, March7-11,200
[27] Jacobsen,K.:Issues and Method for In-Flight and On-Orbit Calibration [C],Workshop on Radiometric and Geometric Calibration, Gulfport,2003, on CD
[28] S.Kocaman, A. Gruen. Orientation And Calibration of ALOS/PRISM Imagery.][JAXA. ALOS PRISM Level1Product Format Descriptions Rev [EB/OL].(2006-10-30)
[29] Gruen A, Kocaman S, Wolff K. Calibration and Validation of EarlyALOS/PRISM Images[J]. The Journal of the Japan Society of Photogrammetryand Remote Sensing, Vol46, No.1, pp:24-38.2007
[30]30Junichi T, Noriko F, Aki G, et al. High Resolution DEM Generation fromALOS PRISM Data-Triplet Image Algorithm Evaluation[C].IEEE InternationalGeoscience and Remote Sensing Symposium,Toulouse,France:2003.
[31]31Takaku J, Tadono T. PRISM On-Orbit Geometric Calibration and DSMPerformance[J]. IEEE Transactions on Geoscience and Remote Sensing.2009,47(12):4060-4073.
[32]32Tadono T, Shimada M, Murakami H, et al. Calibration of PRISM andAVNIR-2Onbroad ALOS"Daichi"[J]. IEEE Transactions on Geoscience andRemote Sensing.2009,47(12):4042-4050.
[33] Gruen A, Kocaman S, Wolff K. Calibration and Validation of EarlyALOS/PRISM Images[J]. The Journal of the Japan Society of Photogrammetryand Remote Sensing, Vol46, No.1, pp:24-38.2007
[34] Kornus,K.,Lehner,M.,Schroeder.Geometric Inflight Calibration of theStereoscopic CCD-Line scanner MOMS-2P[A],ISPRS ComISymp.,Bangalore1998,IntArchPhRS.Vol XXXII-1,PP:148-15].
[35] Seige, P., The MOMS-2P Mission on the Russian Space Station MIR/PRIRODAModule[A]. In: Joint Workshop“Sensors and Mapping from Space”, InternationalSociety for Photogrammetry and Remote Sensing[C], Hannover, Germany,p.11.199].
[36]王任享.三线阵CCD影像卫星摄影测量原理[M].北京:测绘出版社,2006.
[37]王任享.我国无地面控制点卫星摄影测量综述[J].海洋测绘.2008,28(5):1-8.
[38]赵葆常,杨建峰,汶德胜,等.嫦娥一号卫星CCD立体相机的设计与在轨运行[J].航天器工程,2009,18(1):30-36.
[39]赵葆常,杨建峰,贺应红,等.探月光学[J].光子学报,2009,38(3):461-466.
[40] Gerhard Neukum. HRSC:High/Super Resolution Stereo Colour Camera[EB/OL].Http∥:Science&Technology Instrument Ob-jectives.htm.
[41] Ebner H, Ohlhof T, Tang T. Photogrammetric restitution of the Mars’94three-linescanner imagery[J]. SPIE,1993,1943:19-32.
[42] LeroyM. Future europena remote-sensing programs and sensing[J].SPIE,1991,1490:84-85.
[43]杨秉新.国外航天测绘型相机发展概况[J].空间遥感仪器,2002,(5):24-30.
[44]徐鹏.卫星搭载的可见光、近红外光学遥感器[J].空间遥感仪器,2002,(5):|50-56.
[45]于秋水.基于图像处理方法的光学瞄具自动调焦技术研究[D]:[博士学位论文].长春:长春理工大学博士学位论文,2010.
[46]郁道银,谈恒英.工程光学[M].北京:机械工业出版社,1999.
[47] Zhu K F. An effeetive focusing algorithm based on non-uniform sampling [C]IEEE VLSI’2005Suzhou,2005:276-279.
[48]佟首峰,李德志,郝志航.高分辨力TDICCD遥感相机的特性分析[J].光电工程,2001,28(8):64-67.
[49]刘亚侠.TDICCD遥感相机标定技术的研究[D]:[博士学位论文].长春:中国科学院长春光学精密机械与物理研究所,2005.
[50]王文华.大视场遥感相机成像均匀性研究[D]:[博士学位论文].长春:中国科学院长春光学精密机械与物理研究所,2010.
[51]张洪文.空间相机调焦技术的研究[D]:[硕士学位论文].长春:中国科学院长春光学精密机械与物理研究所,2003.
[52]惠守文.长焦距实时航空相机自动调焦技术的研究[D]:[硕士学位论文].长春:中国科学院长春光学精密机械与物理研究所,2003.
[53]王红,韩昌元.温度对航天相机光学系统影响的研究[J].光学技术,2003,29(4):452-454.
[54]王红,田铁印.轴向温差对空间遥感器光学系统成像质量的影响[J].光学精密工程,2007,15(10):1489-1494.
[55]刘洋.空间相机成像质量自动评价方法研究[D]:[硕士学位论文].长春:中国科学院长春光学精密机械与物理研究所,2011.
[56]汤志强.航天线阵CCD传感器严格几何模型的分析与验证[D].[硕士学位论文].郑州:解放军信息工程大学硕士学位论文.2011.
[57]杨俊峰,胡莘,戴勇书.三线阵CCD相机的动态检定[J].解放军测绘研究所学报,2006,19(2):17-22.
[58] Light D L. Characteristics of Remote Sensors for Mapping and Earth ScienceApplications[J].Photogrammetric Engineering&Remote Sensing,1990,56(12):1613-1623.
[59]王任享.无地面控制点卫星摄影测量[J].河南理工大学学报:自然科学版,2005,24(5):329-335.
[60]李朝辉,王智,乔克,等.三线阵立体测绘相机高精度调焦技术及实现[J]2009,36(10):41-46.
[61]胡莘,曹喜滨.三线阵立体测绘卫星的测绘精度分析[J].哈尔滨工业大学学报,2008,40(5):695-699.
[62]曹茂永,孙农亮,郁道银.基于灰度梯度的数字图像评价函数[J].光电工程,2003,30(4):69-72.
[63] Sang Ku Kim S R P, Aug.Simultaneous out-of-focus blur estimation andrestoration for a digital auto-focusing system[J]. IEEE Transactions on ConsumerElectronics,1998,44(3):1071-1075.
[64]孙文.调制传递函数测试仪的自动调焦技术研究[D].[硕士学位论文].南京:南京理工大学,2009.
[65]张辉.CCD图像检测系统自动调焦的研究[D].[硕士学位论文].哈尔滨:哈尔滨工业大学,2007.
[66]赵辉,鲍歌堂,陶卫,等.图像测量中自动调焦函数的实验研究与分析[J].光学精密工程,2004,12(5):531-536.
[67]张旭东,王景峰,程永强,等.多功能一体化模拟摄像机系统设计[J].晶体与显示,2009,24(1):116-120.
[68]王智,张立平,李朝辉.三线阵立体测绘相机构像及误差模型的建立[J].光电工程,37(1):96-100.
[69]李奇,冯华君,徐之海.数字图像清晰度评价函数研究[J].光子学报,2002,31(6):376-378.
[70]白立芬,于水,薛实福,等.基于图像处理的自动调焦方法中清晰度判断函数的研究[J].仪器仪表学报,1999,20(4):85-89.
[71]麦伟麟.光学传递函数及其数理基础[M].国防工业出版社,1978.
[72]庄松林,钱振帮.光学传递函数[M].机械工业出版社,1981.
[73] K. Falconer. Geometry-Mathematical Foundations and Applications[M].NewYork:Wiley,1990.
[74] N. B. Nill B H B. Objective Image Quality Measures Derived From DigitalImage Power Spectra[J]. Optical Engineering,1992,31(4):813-825.
[75] LEE Je-ho K K-s N B-d, et al. Implementation of a passive automatic focusingalgorithm for digital still camera[J]. IEEE Transactions on ConsumerElectronics,1995,41(3):449-454.
[76] R. M. Balboa C W T, N. M. Grzywacz. Occlusions contribute to scaling innatural images[J]. Vision Res,2001,41(7):955-964.
[77] R. M. Balboa C W T, N. M. Grzywacz. Power spectra and distribution ofcontrasts of natural images from different habitats[J].InvestgativeOphthalmology and Visual Science,2001,42:615.
[78]赵志彬.机载光电平台可见光摄像机自动调焦技术研究[D]:[硕士学位论文].长春:中国科学院长春光学精密机械与物理研究所学位论文,2010.
[79]修吉宏.基于图像功率谱的航空图像质量判别技术研究[D]:[博士学位论文].长春:中国科学院长春光学精密机械与物理研究所学位论文,2005.
[80]张影.三线阵CCD立体测绘相机总体技术研究[D]:[博士学位论文].长春:长春理工大学博士学位论文,2009.
[81]王红,田铁印.三线阵测绘相机光学系统设计的设计和公差分析.光学精密工程,2011,19(7):1444-1450.
[82]赖祖武,包宗明,王长河,等.抗辐射电子学:辐射效应及加固原理[M].北京:国防工业出版社,1998.
[83]杜坤梅,李铁才.电机控制技术[M].哈尔滨:哈尔滨工业大学出版社,2002.
[84]金茂椿,魏家轼.电机与控制[M].西安:电子科技大学出版社,1992.
[85]张志刚,光电编码器细分误差分析及补偿研究[D]:[硕士学位论文].哈尔滨:哈尔滨工业大学控制科学与工程系,2010.
[86]陈赟.单圈对式光电轴角编码器原理的研究[D]:[博士学位论文].长春:中国科学院长春光学精密机械与物理研究所,2006.
[87]佘琳.编码器光电信号参数测量及细分误差评估[D]:[硕士学位论文].长春:中国科学院长春光学精密机械与物理研究所,2003.
[88]费业泰.误差理论与数据处理[M].北京:机械工业出版社,1995.
[89]毛英泰.误差理论与精度分析[M].北京:国防出版社,1982.
[90]邓先礼.最优化技术[M].重庆:重庆大学出版社,1998.
[91]粟塔山.最优化计算原理与算法程序设计[M].长沙:国防科技大学出版社,2001.
[92]任四刚.图像式自动聚焦系统及其测量技术的研究[D]:[硕士学位论文].重庆:重庆大学,2002.
[93]田宜彬.数字成像系统的自动对焦算法研究[D]:[硕士学位论文].杭州:浙江大学.2002,
[94]宫光勇,何文忠,高旭辉.红外系统中自动调焦爬山搜索算法的优化设计[J].激光与红外,2007,37(11):1213-1215.
[95] He J Z R Z, Hong Z L. Modified Fast Climbing Search Auto-focus Algorithmwith Adaptive Step Size Searching Technique for Digital Camera[J]. ConsumerElectronics,1999,(6):92-93.
[96]朱孔凤,姜威,高赞.自动聚焦系统中聚焦窗口的选择及参量的确定[J].光学学报,2006,26(6):836-840.
[97]张文爱,李逢磊,程永强.基于FPGA的步进电机驱动及自动聚焦的实现[J].电子技术应用,2008,25(5):33-34.
[98]任四刚,李见为,谢利利.基于灰度差分法的自动调焦技术[J].光电工程,2003,30(2):53-55.
[99]王欣,安志勇,杨瑞宁.基于图像清晰度评价函数的CCD摄像机自动调焦技术研究[J].长春理工大学学报(自然科学版),2008,31(1):11-14.
[100]王智,张立平,李朝辉,荀显超.传输型立体测绘相机的调焦机构设计[J].光学精密工程,2009,17(5):1051-1055.
[101]吕世良,王晓茜,刘金国,等.基于单片机的星载相机调焦控制系统的设计与实现[J].微计算机信息,2010,26(11-2):3-5.
[102]王昕,王海霞,徐抒岩,等.遥感相机自动检焦技术研究[J].光学技术,2006,32(suppl):344-350.
[103]张海青,张立平,王智.航天立体测绘相机调焦机构的设计与实验研究[J].机械设计与制造,2009(4)57-59.
[104]吕世良,刘金国,贾平.空间多光谱CCD相机调焦精度分析[J].红外与激光工程.2013,42(2):392-397.
[105]吕世良,刘金国,贾平,徐东.多光谱相机调焦系统设计[J].光学精密工程.2014,35(4):207-210.
[106]张祖勋,张剑清.数字摄影测量学[M].武汉:武汉大学出版社,1997
[107]吴培中.陆地卫星类别、应用与发展[J].卫星应用,1993(3):13-15.
[108]吕世良.动态目标模拟器转台稳速精度分析[J].电子测量技术,2012,35(1):50-54.
[109]李如豹.航天型号软件测试的计划技术研究[D]:[硕士学位论文].北京:北京工业大学,2003.
[110]李芳华.星载软件可靠性设计方法[J].上海航天,2003(3):24-27.
[111]陈世平.空间相机设计与试验[M].北京:宇航出版社,2003.
[112]李积慧,韩双丽,王家骐,等.空间相机的热分析与热控制技术[J].光学精密工程,1999,7(6):36-41.
[113]雷蓉.星载线阵传感器在轨几何标定的理论与算法研究[D]:[博士学位论文].郑州:信息工程大学,2011,46-47.
[114] IERS2000. http://maia.usno.navy.mil/conv2000.html.
[115]卢振华.推扫式遥感相机基于图像的实时自动调焦研究[D]:[博士学位论文].长春:中国科学院长春光学精密机械与物理研究所学位论文,2011.
[116]李奇.数字自动对焦技术理论及实现方法[D]:[博士学位论文].杭州:浙江大学,2004.
[117]陈国金.数字图像自动聚焦技术研究及系统实现[D]:[博士学位论文].西安:西安电子科技大学,2007.
[2]姜景山主编.空间科学与应用[M].北京:科学出版社,2001.5-15.
[3]孙承志,唐新明,翟亮.我国测绘卫星的发展思路和应用展望[J].测绘科学,2009,3,34(2):5-7.
[4]贾平,郝志航,金光等主编.三线阵CCD立体测绘技术及其应用[M].长春光机所,2004.1-4.
[5]王之卓.摄影测量原理[M].北京测绘出版社,1979.5-7.
[6]白杉,杨秉新.航天侦察相机的发展和研发[J].影像技术,2006,2:3-6.
[7]马文坡.航天光学遥感技术[M].北京:中国科学技术出版社,2010.1-7.
[8]魏雯,李浩悦.俄罗斯军事成像侦察卫星的现状与发展[J].中国航天,2011(7):23-26.
[9]卢崇顶.国外遥感卫星发展简介(1)[J].上海地质,2001(3):28-35.
[10]庞征.法国拟打造新型太空间谍“多国天基成像系统”[J].太空探索,2011(3):48-51.
[11] Valorge,C.,40years of experience with SPOT in-flight calibration[C],ISPRSInternational workshop on radiometric and geometric calibration,Gulfport,2-5Dec200.
[12]王任享.论不同航天摄影测量传感器的摄影测量性能[J].测绘科技学报,2002(2):95-99.
[13]陈尊充,陈炳桐.关于大比例尺航测成图的体会[J].城市勘探.2002,(3):25-30
[14]王任享.无地面控制点卫星摄影测量[J].河南理工大学学报:自然科学版,2005,24(5):329-335.
[15]王任享,李晶,王新义,杨俊锋.无地面控制点卫星摄影测量高程误差估算[J]测绘科学.2005,30(6):9-11.
[16]王任享.我国无地面控制点摄影测量卫星相机[J].航天返回与遥感,2008,29(3):6-10.
[17]王任享,李晶,王新义,等.无地面控制点卫星摄影测量高程误差估算[J].测绘科学,2005,30(6):9-11.
[18]李朝辉,王智,乔克,等.三线阵立体测绘相机高精度调焦技术及实现[J].光电工程,2009,36(10):41-42.
[19]胡莘,曹喜滨.三线阵立体测绘卫星的测绘精度分析[J].哈尔滨工业大学学报,2008,40(5):695-699.
[20]李树楷.遥感时空信息集成技术及其应用[M].北京:科学技术出版社,2003,6-7.
[21]刘金国,郝志航,金光.三线阵CCD立体测绘技术及其应用[M].长春:中国科学院长春光学精密机械与物理研究所,2004,1-2.
[22] SPOT IMAGE Technical Data [OL] URL:http://www.spotimage.fr/home/system/introsat/seltec/welcome.htm,2006-10-8.
[23] Breton, E,2002, Pre-flight and in-flight geometric calibration of SPOT5HRGand HRS images. ISPRS Comm.I, Denver,CO,10-15Nov2002.
[24]姬渊.缺少控制点条件下的SPOT遥感影像定位技术研究[D]:[硕士学位论文].郑州:信息工程大学,2008.
[25]苏文博,范大昭. SPOT无控制和基于严密成像模型的研究[J].测绘与空间地理信息,2009,32(5):18-22.
[26] Jacke Grodecki and James Lutes. IKONOS Geometric Calibrations[C], Presented at ASPRS2005, Baltimore, Maryland, March7-11,200
[27] Jacobsen,K.:Issues and Method for In-Flight and On-Orbit Calibration [C],Workshop on Radiometric and Geometric Calibration, Gulfport,2003, on CD
[28] S.Kocaman, A. Gruen. Orientation And Calibration of ALOS/PRISM Imagery.][JAXA. ALOS PRISM Level1Product Format Descriptions Rev [EB/OL].(2006-10-30)
[29] Gruen A, Kocaman S, Wolff K. Calibration and Validation of EarlyALOS/PRISM Images[J]. The Journal of the Japan Society of Photogrammetryand Remote Sensing, Vol46, No.1, pp:24-38.2007
[30]30Junichi T, Noriko F, Aki G, et al. High Resolution DEM Generation fromALOS PRISM Data-Triplet Image Algorithm Evaluation[C].IEEE InternationalGeoscience and Remote Sensing Symposium,Toulouse,France:2003.
[31]31Takaku J, Tadono T. PRISM On-Orbit Geometric Calibration and DSMPerformance[J]. IEEE Transactions on Geoscience and Remote Sensing.2009,47(12):4060-4073.
[32]32Tadono T, Shimada M, Murakami H, et al. Calibration of PRISM andAVNIR-2Onbroad ALOS"Daichi"[J]. IEEE Transactions on Geoscience andRemote Sensing.2009,47(12):4042-4050.
[33] Gruen A, Kocaman S, Wolff K. Calibration and Validation of EarlyALOS/PRISM Images[J]. The Journal of the Japan Society of Photogrammetryand Remote Sensing, Vol46, No.1, pp:24-38.2007
[34] Kornus,K.,Lehner,M.,Schroeder.Geometric Inflight Calibration of theStereoscopic CCD-Line scanner MOMS-2P[A],ISPRS ComISymp.,Bangalore1998,IntArchPhRS.Vol XXXII-1,PP:148-15].
[35] Seige, P., The MOMS-2P Mission on the Russian Space Station MIR/PRIRODAModule[A]. In: Joint Workshop“Sensors and Mapping from Space”, InternationalSociety for Photogrammetry and Remote Sensing[C], Hannover, Germany,p.11.199].
[36]王任享.三线阵CCD影像卫星摄影测量原理[M].北京:测绘出版社,2006.
[37]王任享.我国无地面控制点卫星摄影测量综述[J].海洋测绘.2008,28(5):1-8.
[38]赵葆常,杨建峰,汶德胜,等.嫦娥一号卫星CCD立体相机的设计与在轨运行[J].航天器工程,2009,18(1):30-36.
[39]赵葆常,杨建峰,贺应红,等.探月光学[J].光子学报,2009,38(3):461-466.
[40] Gerhard Neukum. HRSC:High/Super Resolution Stereo Colour Camera[EB/OL].Http∥:Science&Technology Instrument Ob-jectives.htm.
[41] Ebner H, Ohlhof T, Tang T. Photogrammetric restitution of the Mars’94three-linescanner imagery[J]. SPIE,1993,1943:19-32.
[42] LeroyM. Future europena remote-sensing programs and sensing[J].SPIE,1991,1490:84-85.
[43]杨秉新.国外航天测绘型相机发展概况[J].空间遥感仪器,2002,(5):24-30.
[44]徐鹏.卫星搭载的可见光、近红外光学遥感器[J].空间遥感仪器,2002,(5):|50-56.
[45]于秋水.基于图像处理方法的光学瞄具自动调焦技术研究[D]:[博士学位论文].长春:长春理工大学博士学位论文,2010.
[46]郁道银,谈恒英.工程光学[M].北京:机械工业出版社,1999.
[47] Zhu K F. An effeetive focusing algorithm based on non-uniform sampling [C]IEEE VLSI’2005Suzhou,2005:276-279.
[48]佟首峰,李德志,郝志航.高分辨力TDICCD遥感相机的特性分析[J].光电工程,2001,28(8):64-67.
[49]刘亚侠.TDICCD遥感相机标定技术的研究[D]:[博士学位论文].长春:中国科学院长春光学精密机械与物理研究所,2005.
[50]王文华.大视场遥感相机成像均匀性研究[D]:[博士学位论文].长春:中国科学院长春光学精密机械与物理研究所,2010.
[51]张洪文.空间相机调焦技术的研究[D]:[硕士学位论文].长春:中国科学院长春光学精密机械与物理研究所,2003.
[52]惠守文.长焦距实时航空相机自动调焦技术的研究[D]:[硕士学位论文].长春:中国科学院长春光学精密机械与物理研究所,2003.
[53]王红,韩昌元.温度对航天相机光学系统影响的研究[J].光学技术,2003,29(4):452-454.
[54]王红,田铁印.轴向温差对空间遥感器光学系统成像质量的影响[J].光学精密工程,2007,15(10):1489-1494.
[55]刘洋.空间相机成像质量自动评价方法研究[D]:[硕士学位论文].长春:中国科学院长春光学精密机械与物理研究所,2011.
[56]汤志强.航天线阵CCD传感器严格几何模型的分析与验证[D].[硕士学位论文].郑州:解放军信息工程大学硕士学位论文.2011.
[57]杨俊峰,胡莘,戴勇书.三线阵CCD相机的动态检定[J].解放军测绘研究所学报,2006,19(2):17-22.
[58] Light D L. Characteristics of Remote Sensors for Mapping and Earth ScienceApplications[J].Photogrammetric Engineering&Remote Sensing,1990,56(12):1613-1623.
[59]王任享.无地面控制点卫星摄影测量[J].河南理工大学学报:自然科学版,2005,24(5):329-335.
[60]李朝辉,王智,乔克,等.三线阵立体测绘相机高精度调焦技术及实现[J]2009,36(10):41-46.
[61]胡莘,曹喜滨.三线阵立体测绘卫星的测绘精度分析[J].哈尔滨工业大学学报,2008,40(5):695-699.
[62]曹茂永,孙农亮,郁道银.基于灰度梯度的数字图像评价函数[J].光电工程,2003,30(4):69-72.
[63] Sang Ku Kim S R P, Aug.Simultaneous out-of-focus blur estimation andrestoration for a digital auto-focusing system[J]. IEEE Transactions on ConsumerElectronics,1998,44(3):1071-1075.
[64]孙文.调制传递函数测试仪的自动调焦技术研究[D].[硕士学位论文].南京:南京理工大学,2009.
[65]张辉.CCD图像检测系统自动调焦的研究[D].[硕士学位论文].哈尔滨:哈尔滨工业大学,2007.
[66]赵辉,鲍歌堂,陶卫,等.图像测量中自动调焦函数的实验研究与分析[J].光学精密工程,2004,12(5):531-536.
[67]张旭东,王景峰,程永强,等.多功能一体化模拟摄像机系统设计[J].晶体与显示,2009,24(1):116-120.
[68]王智,张立平,李朝辉.三线阵立体测绘相机构像及误差模型的建立[J].光电工程,37(1):96-100.
[69]李奇,冯华君,徐之海.数字图像清晰度评价函数研究[J].光子学报,2002,31(6):376-378.
[70]白立芬,于水,薛实福,等.基于图像处理的自动调焦方法中清晰度判断函数的研究[J].仪器仪表学报,1999,20(4):85-89.
[71]麦伟麟.光学传递函数及其数理基础[M].国防工业出版社,1978.
[72]庄松林,钱振帮.光学传递函数[M].机械工业出版社,1981.
[73] K. Falconer. Geometry-Mathematical Foundations and Applications[M].NewYork:Wiley,1990.
[74] N. B. Nill B H B. Objective Image Quality Measures Derived From DigitalImage Power Spectra[J]. Optical Engineering,1992,31(4):813-825.
[75] LEE Je-ho K K-s N B-d, et al. Implementation of a passive automatic focusingalgorithm for digital still camera[J]. IEEE Transactions on ConsumerElectronics,1995,41(3):449-454.
[76] R. M. Balboa C W T, N. M. Grzywacz. Occlusions contribute to scaling innatural images[J]. Vision Res,2001,41(7):955-964.
[77] R. M. Balboa C W T, N. M. Grzywacz. Power spectra and distribution ofcontrasts of natural images from different habitats[J].InvestgativeOphthalmology and Visual Science,2001,42:615.
[78]赵志彬.机载光电平台可见光摄像机自动调焦技术研究[D]:[硕士学位论文].长春:中国科学院长春光学精密机械与物理研究所学位论文,2010.
[79]修吉宏.基于图像功率谱的航空图像质量判别技术研究[D]:[博士学位论文].长春:中国科学院长春光学精密机械与物理研究所学位论文,2005.
[80]张影.三线阵CCD立体测绘相机总体技术研究[D]:[博士学位论文].长春:长春理工大学博士学位论文,2009.
[81]王红,田铁印.三线阵测绘相机光学系统设计的设计和公差分析.光学精密工程,2011,19(7):1444-1450.
[82]赖祖武,包宗明,王长河,等.抗辐射电子学:辐射效应及加固原理[M].北京:国防工业出版社,1998.
[83]杜坤梅,李铁才.电机控制技术[M].哈尔滨:哈尔滨工业大学出版社,2002.
[84]金茂椿,魏家轼.电机与控制[M].西安:电子科技大学出版社,1992.
[85]张志刚,光电编码器细分误差分析及补偿研究[D]:[硕士学位论文].哈尔滨:哈尔滨工业大学控制科学与工程系,2010.
[86]陈赟.单圈对式光电轴角编码器原理的研究[D]:[博士学位论文].长春:中国科学院长春光学精密机械与物理研究所,2006.
[87]佘琳.编码器光电信号参数测量及细分误差评估[D]:[硕士学位论文].长春:中国科学院长春光学精密机械与物理研究所,2003.
[88]费业泰.误差理论与数据处理[M].北京:机械工业出版社,1995.
[89]毛英泰.误差理论与精度分析[M].北京:国防出版社,1982.
[90]邓先礼.最优化技术[M].重庆:重庆大学出版社,1998.
[91]粟塔山.最优化计算原理与算法程序设计[M].长沙:国防科技大学出版社,2001.
[92]任四刚.图像式自动聚焦系统及其测量技术的研究[D]:[硕士学位论文].重庆:重庆大学,2002.
[93]田宜彬.数字成像系统的自动对焦算法研究[D]:[硕士学位论文].杭州:浙江大学.2002,
[94]宫光勇,何文忠,高旭辉.红外系统中自动调焦爬山搜索算法的优化设计[J].激光与红外,2007,37(11):1213-1215.
[95] He J Z R Z, Hong Z L. Modified Fast Climbing Search Auto-focus Algorithmwith Adaptive Step Size Searching Technique for Digital Camera[J]. ConsumerElectronics,1999,(6):92-93.
[96]朱孔凤,姜威,高赞.自动聚焦系统中聚焦窗口的选择及参量的确定[J].光学学报,2006,26(6):836-840.
[97]张文爱,李逢磊,程永强.基于FPGA的步进电机驱动及自动聚焦的实现[J].电子技术应用,2008,25(5):33-34.
[98]任四刚,李见为,谢利利.基于灰度差分法的自动调焦技术[J].光电工程,2003,30(2):53-55.
[99]王欣,安志勇,杨瑞宁.基于图像清晰度评价函数的CCD摄像机自动调焦技术研究[J].长春理工大学学报(自然科学版),2008,31(1):11-14.
[100]王智,张立平,李朝辉,荀显超.传输型立体测绘相机的调焦机构设计[J].光学精密工程,2009,17(5):1051-1055.
[101]吕世良,王晓茜,刘金国,等.基于单片机的星载相机调焦控制系统的设计与实现[J].微计算机信息,2010,26(11-2):3-5.
[102]王昕,王海霞,徐抒岩,等.遥感相机自动检焦技术研究[J].光学技术,2006,32(suppl):344-350.
[103]张海青,张立平,王智.航天立体测绘相机调焦机构的设计与实验研究[J].机械设计与制造,2009(4)57-59.
[104]吕世良,刘金国,贾平.空间多光谱CCD相机调焦精度分析[J].红外与激光工程.2013,42(2):392-397.
[105]吕世良,刘金国,贾平,徐东.多光谱相机调焦系统设计[J].光学精密工程.2014,35(4):207-210.
[106]张祖勋,张剑清.数字摄影测量学[M].武汉:武汉大学出版社,1997
[107]吴培中.陆地卫星类别、应用与发展[J].卫星应用,1993(3):13-15.
[108]吕世良.动态目标模拟器转台稳速精度分析[J].电子测量技术,2012,35(1):50-54.
[109]李如豹.航天型号软件测试的计划技术研究[D]:[硕士学位论文].北京:北京工业大学,2003.
[110]李芳华.星载软件可靠性设计方法[J].上海航天,2003(3):24-27.
[111]陈世平.空间相机设计与试验[M].北京:宇航出版社,2003.
[112]李积慧,韩双丽,王家骐,等.空间相机的热分析与热控制技术[J].光学精密工程,1999,7(6):36-41.
[113]雷蓉.星载线阵传感器在轨几何标定的理论与算法研究[D]:[博士学位论文].郑州:信息工程大学,2011,46-47.
[114] IERS2000. http://maia.usno.navy.mil/conv2000.html.
[115]卢振华.推扫式遥感相机基于图像的实时自动调焦研究[D]:[博士学位论文].长春:中国科学院长春光学精密机械与物理研究所学位论文,2011.
[116]李奇.数字自动对焦技术理论及实现方法[D]:[博士学位论文].杭州:浙江大学,2004.
[117]陈国金.数字图像自动聚焦技术研究及系统实现[D]:[博士学位论文].西安:西安电子科技大学,2007.